一、在图 24-2上运行Dijkstra算法,第一次使用结点 s s s作为源结点,第二次使用结点 z z z作为源结点。以类似于图 24-6 的风格,给出每次while循环后的 d d d值和 π π π值,以及集合 S S S中的所有结点。如果要写代码,请用go语言。
文心一言:
在图 24-2 上运行 Dijkstra 算法,我们可以模拟算法的执行过程,并给出每次 while 循环后的 d d d 值、 π \pi π 值和集合 S S S 中的结点。Dijkstra 算法用于计算从源节点到所有其他节点的最短路径。
假设图 24-2 如下所示(假设边权重为非负):
s ---- 2 ---- t
| | |
4 | 3 1|
v v v
u ---- 1 ---- z
|
5
v
w
第一次运行 Dijkstra 算法,源节点为 s s s
-
初始化:
- d [ s ] = 0 d[s] = 0 d[s]=0
- d [ u ] = ∞ d[u] = \infty d[u]=∞
- d [ t ] = ∞ d[t] = \infty d[t]=∞
- d [ z ] = ∞ d[z] = \infty d[z]=∞
- d [ w ] = ∞ d[w] = \infty d[w]=∞
- π [ s ] = nil \pi[s] = \text{nil} π[s]=nil
- π [ u ] = s \pi[u] = s π[u]=s
- π [ t ] = s \pi[t] = s π[t]=s
- π [ z ] = s \pi[z] = s π[z]=s
- π [ w ] = s \pi[w] = s π[w]=s
- S = ∅ S = \emptyset S=∅
-
第一次 while 循环:
-
选择 d d d 值最小的节点 s s s, d [ s ] = 0 d[s] = 0 d[s]=0
-
将 s s s 添加到 S S S, S = { s } S = \{s\} S={s}
-
更新邻居:
- u u u: d [ u ] = min ( d [ u ] , d [ s ] + 4 ) = min ( ∞ , 0 + 4 ) = 4 d[u] = \min(d[u], d[s] + 4) = \min(\infty, 0 + 4) = 4 d[u]=min(d[u],d[s]+4)=min(∞,0+4)=4
- t t t: d [ t ] = min ( d [ t ] , d [ s ] + 2 ) = min ( ∞ , 0 + 2 ) = 2 d[t] = \min(d[t], d[s] + 2) = \min(\infty, 0 + 2) = 2 d[t]=min(d[t],d[s]+2)=min(∞,0+2)=2
-
结果:
- d = [ 0 , 4 , 2 , ∞ , ∞ ] d = [0, 4, 2, \infty, \infty] d=[0,4,2,∞,∞]
- π = [ nil , s , s , s , s ] \pi = [\text{nil}, s, s, s, s] π=[nil,s,s,s,s]
- S = { s } S = \{s\} S={s}
-
-
第二次 while 循环:
-
选择 d d d 值最小的节点 t t t, d [ t ] = 2 d[t] = 2 d[t]=2
-
将 t t t 添加到 S S S, S = { s , t } S = \{s, t\} S={s,t}
-
更新邻居:
- u u u: d [ u ] = min ( d [ u ] , d [ t ] + 3 ) = min ( 4 , 2 + 3 ) = 4 d[u] = \min(d[u], d[t] + 3) = \min(4, 2 + 3) = 4 d[u]=min(d[u],d[t]+3)=min(4,2+3)=4
- z z z: d [ z ] = min ( d [ z ] , d [ t ] + 1 ) = min ( ∞ , 2 + 1 ) = 3 d[z] = \min(d[z], d[t] + 1) = \min(\infty, 2 + 1) = 3 d[z]=min(d[z],d[t]+1)=min(∞,2+1)=3
-
结果:
- d = [ 0 , 4 , 2 , 3 , ∞ ] d = [0, 4, 2, 3, \infty] d=[0,4,2,3,∞]
- π = [ nil , s , s , t , s ] \pi = [\text{nil}, s, s, t, s] π=[nil,s,s,t,s]
- S = { s , t } S = \{s, t\} S={s,t}
-
-
第三次 while 循环:
-
选择 d d d 值最小的节点 z z z, d [ z ] = 3 d[z] = 3 d[z]=3
-
将 z z z 添加到 S S S, S = { s , t , z } S = \{s, t, z\} S={s,t,z}
-
更新邻居:
- u u u: d [ u ] = min ( d [ u ] , d [ z ] + 1 ) = min ( 4 , 3 + 1 ) = 4 d[u] = \min(d[u], d[z] + 1) = \min(4, 3 + 1) = 4 d[u]=min(d[u],d[z]+1)=min(4,3+1)=4
-
结果:
- d = [ 0 , 4 , 2 , 3 , ∞ ] d = [0, 4, 2, 3, \infty] d=[0,4,2,3,∞]
- π = [ nil , s , s , t , s ] \pi = [\text{nil}, s, s, t, s] π=[nil,s,s,t,s]
- S = { s , t , z } S = \{s, t, z\} S={s,t,z}
-
-
第四次 while 循环:
-
选择 d d d 值最小的节点 u u u, d [ u ] = 4 d[u] = 4 d[u]=4
-
将 u u u 添加到 S S S, S = { s , t , z , u } S = \{s, t, z, u\} S={s,t,z,u}
-
更新邻居:
- w w w: d [ w ] = min ( d [ w ] , d [ u ] + 5 ) = min ( ∞ , 4 + 5 ) = 9 d[w] = \min(d[w], d[u] + 5) = \min(\infty, 4 + 5) = 9 d[w]=min(d[w],d[u]+5)=min(∞,4+5)=9
-
结果:
- d = [ 0 , 4 , 2 , 3 , 9 ] d = [0, 4, 2, 3, 9] d=[0,4,2,3,9]
- π = [ nil , s , s , t , u ] \pi = [\text{nil}, s, s, t, u] π=[nil,s,s,t,u]
- S = { s , t , z , u } S = \{s, t, z, u\} S={s,t,z,u}
-
-
第五次 while 循环:
-
选择 d d d 值最小的节点 w w w, d [ w ] = 9 d[w] = 9 d[w]=9
-
将 w w w 添加到 S S S, S = { s , t , z , u , w } S = \{s, t, z, u, w\} S={s,t,z,u,w}
-
结果:
- d = [ 0 , 4 , 2 , 3 , 9 ] d = [0, 4, 2, 3, 9] d=[0,4,2,3,9]
- π = [ nil , s , s , t , u ] \pi = [\text{nil}, s, s, t, u] π=[nil,s,s,t,u]
- S = { s , t , z , u , w } S = \{s, t, z, u, w\} S={s,t,z,u,w}
-
第二次运行 Dijkstra 算法,源节点为 z z z
-
初始化:
- d [ s ] = ∞ d[s] = \infty d[s]=∞
- d [ u ] = ∞ d[u] = \infty d[u]=∞
- d [ t ] = ∞ d[t] = \infty d[t]=∞
- d [ z ] = 0 d[z] = 0 d[z]=0
- d [ w ] = ∞ d[w] = \infty d[w]=∞
- π [ s ] = z \pi[s] = z π[s]=z
- π [ u ] = z \pi[u] = z π[u]=z
- π [ t ] = z \pi[t] = z π[t]=z
- π [ z ] = nil \pi[z] = \text{nil} π[z]=nil
- π [ w ] = z \pi[w] = z π[w]=z
- S = ∅ S = \emptyset S=∅
-
第一次 while 循环:
-
选择 d d d 值最小的节点 z z z, d [ z ] = 0 d[z] = 0 d[z]=0
-
将 z z z 添加到 S S S, S = { z } S = \{z\} S={z}
-
更新邻居:
- t t t: d [ t ] = min ( d [ t ] , d [ z ] + 1 ) = min ( ∞ , 0 + 1 ) = 1 d[t] = \min(d[t], d[z] + 1) = \min(\infty, 0 + 1) = 1 d[t]=min(d[t],d[z]+1)=min(∞,0+1)=1
- u u u: d [ u ] = min ( d [ u ] , d [ z ] + 1 ) = min ( ∞ , 0 + 1 ) = 1 d[u] = \min(d[u], d[z] + 1) = \min(\infty, 0 + 1) = 1 d[u]=min(d[u],d[z]+1)=min(∞,0+1)=1
-
结果:
- d = [ ∞ , 1 , 1 , 0 , ∞ ] d = [\infty, 1, 1, 0, \infty] d=[∞,1,1,0,∞]
- π = [ z , z , z , nil , z ] \pi = [z, z, z, \text{nil}, z] π=[z,z,z,nil,z]
- S = { z } S = \{z\} S={z}
-
-
第二次 while 循环:
-
选择 d d d 值最小的节点 t t t 和 u u u,假设选择 t t t(因为两者相等,顺序不影响结果)
-
将 t t t 添加到 S S S, S = { z , t } S = \{z, t\} S={z,t}
-
更新邻居:
- u u u: d [ u ] = min ( d [ u ] , d [ t ] + 3 ) = min ( 1 , 1 + 3 ) = 1 d[u] = \min(d[u], d[t] + 3) = \min(1, 1 + 3) = 1 d[u]=min(d[u],d[t]+3)=min(1,1+3)=1
- s s s: d [ s ] = min ( d [ s ] , d [ t ] + 2 ) = min ( ∞ , 1 + 2 ) = 3 d[s] = \min(d[s], d[t] + 2) = \min(\infty, 1 + 2) = 3 d[s]=min(d[s],d[t]+2)=min(∞,1+2)=3
-
结果:
- d = [ 3 , 1 , 1 , 0 , ∞ ] d = [3, 1, 1, 0, \infty] d=[3,1,1,0,∞]
- π = [ t , z , z , nil , z ] \pi = [t, z, z, \text{nil}, z] π=[t,z,z,nil,z]
- S = { z , t } S = \{z, t\} S={z,t}
-
-
第三次 while 循环:
-
选择 d d d 值最小的节点 u u u
-
将 u u u 添加到 S S S, S = { z , t , u } S = \{z, t, u\} S={z,t,u}
-
更新邻居:
- w w w: d [ w ] = min ( d [ w ] , d [ u ] + 5 ) = min ( ∞ , 1 + 5 ) = 6 d[w] = \min(d[w], d[u] + 5) = \min(\infty, 1 + 5) = 6 d[w]=min(d[w],d[u]+5)=min(∞,1+5)=6
-
结果:
- d = [ 3 , 1 , 1 , 0 , 6 ] d = [3, 1, 1, 0, 6] d=[3,1,1,0,6]
- π = [ t , z , z , nil , u ] \pi = [t, z, z, \text{nil}, u] π=[t,z,z,nil,u]
- S = { z , t , u } S = \{z, t, u\} S={z,t,u}
-
-
第四次 while 循环:
-
选择 d d d 值最小的节点 s s s
-
将 s s s 添加到 S S S, S = { z , t , u , s } S = \{z, t, u, s\} S={z,t,u,s}
-
没有需要更新的邻居。
-
结果:
- d = [ 3 , 1 , 1 , 0 , 6 ] d = [3, 1, 1, 0, 6] d=[3,1,1,0,6]
- π = [ t , z , z , nil , u ] \pi = [t, z, z, \text{nil}, u] π=[t,z,z,nil,u]
- S = { z , t , u , s } S = \{z, t, u, s\} S={z,t,u,s}
-
-
第五次 while 循环:
-
选择 d d d 值最小的节点 w w w
-
将 w w w 添加到 S S S, S = { z , t , u , s , w } S = \{z, t, u, s, w\} S={z,t,u,s,w}
-
结果:
- $d = [3, 1, 1,
-
讯飞星火:
首先,我们需要明确图 24-2 的结构和权重。假设我们已经有了一个表示图的数据结构,例如邻接矩阵或邻接列表。然后,我们可以使用 Dijkstra 算法来计算从源节点到其他所有节点的最短路径。
以下是使用 Go 语言实现 Dijkstra 算法的代码:
package main
import (
"fmt"
"math"
)
type Graph struct {
vertices int
edges [][]int
}
func NewGraph(v int) *Graph {
return &Graph{
vertices: v,
edges: make([][]int, v),
}
}
func (g *Graph) AddEdge(u, v, w int) {
g.edges[u] = append(g.edges[u], v)
g.edges[v] = append(g.edges[v], u)
}
func dijkstra(graph *Graph, src int) ([]int, []int) {
dist := make([]int, graph.vertices)
prev := make([]int, graph.vertices)
visited := make([]bool, graph.vertices)
for i := 0; i < graph.vertices; i++ {
dist[i] = math.MaxInt32
prev[i] = -1
}
dist[src] = 0
for i := 0; i < graph.vertices; i++ {
minDist := math.MaxInt32
minIndex := -1
for j := 0; j < graph.vertices; j++ {
if !visited[j] && dist[j] < minDist {
minDist = dist[j]
minIndex = j
}
}
if minIndex == -1 {
break
}
visited[minIndex] = true
for _, neighbor := range graph.edges[minIndex] {
alt := dist[minIndex] + 1 // Assuming all edges have weight 1
if alt < dist[neighbor] {
dist[neighbor] = alt
prev[neighbor] = minIndex
}
}
}
return dist, prev
}
func main() {
// Create the graph and add edges (assuming weights are 1 for simplicity)
graph := NewGraph(6)
graph.AddEdge(0, 1, 1)
graph.AddEdge(0, 2, 1)
graph.AddEdge(1, 3, 1)
graph.AddEdge(2, 3, 1)
graph.AddEdge(3, 4, 1)
graph.AddEdge(4, 5, 1)
// Run Dijkstra's algorithm from source node s (0)
distS, prevS := dijkstra(graph, 0)
fmt.Println("Distances from source s:", distS)
fmt.Println("Predecessors from source s:", prevS)
// Run Dijkstra's algorithm from source node z (5)
distZ, prevZ := dijkstra(graph, 5)
fmt.Println("Distances from source z:", distZ)
fmt.Println("Predecessors from source z:", prevZ)
}
请注意,这个代码示例假设所有边的权重都是1。在实际应用中,您需要根据实际权重调整代码。此外,这个代码示例没有输出每次循环后的
d
d
d 值和
π
π
π 值以及集合
S
S
S 中的所有结点。要实现这一点,您可以在 dijkstra 函数中添加适当的打印语句来显示这些信息。
360智脑:
由于我无法直接查看图像或图表(图 24-2),我将提供一个通用的Go语言代码示例,用于实现Dijkstra算法,并解释如何使用它来处理您的问题。您需要将图的邻接矩阵或邻接列表转换为代码中使用的数据结构,并根据您的图的具体情况调整代码。
以下是一个简单的Dijkstra算法的Go语言实现:
package main
import (
"container/heap"
"fmt"
)
// An Item is something we manage in a priority queue.
type Item struct {
node int // The node index.
dist int // The distance from the source to this node.
index int // The index of the item in the heap.
}
// A PriorityQueue implements heap.Interface and holds Items.
type PriorityQueue []*Item
func (pq PriorityQueue) Len() int { return len(pq) }
func (pq PriorityQueue) Less(i, j int) bool {
// We want Pop to give us the lowest distance, so we use less than here.
return pq[i].dist < pq[j].dist
}
func (pq PriorityQueue) Swap(i, j int) {
pq[i], pq[j] = pq[j], pq[i]
pq[i].index = i
pq[j].index = j
}
func (pq *PriorityQueue) Push(x interface{}) {
n := len(*pq)
item := x.(*Item)
item.index = n
*pq = append(*pq, item)
}
func (pq *PriorityQueue) Pop() interface{} {
old := *pq
n := len(old)
item := old[n-1]
old[n-1] = nil // avoid memory leak
item.index = -1 // for safety
*pq = old[0 : n-1]
return item
}
// Dijkstra's algorithm
func Dijkstra(graph [][]int, src int) ([]int, []int) {
n := len(graph)
d := make([]int, n)
pi := make([]int, n)
pq := make(PriorityQueue, n)
for i := range d {
d[i] = 1<<31 - 1 // Initialize distances as infinity
pi[i] = -1 // No parent initially
pq[i] = &Item{node: i, dist: d[i], index: i}
}
d[src] = 0 // Distance to source is 0
heap.Init(&pq)
for pq.Len() > 0 {
u := heap.Pop(&pq).(*Item)
for v := 0; v < n; v++ {
if graph[u.node][v] != 0 { // There is an edge from u to v
alt := d[u.node] + graph[u.node][v]
if alt < d[v] {
d[v] = alt
pi[v] = u.node
heap.Fix(&pq, pq[v].index)
}
}
}
}
return d, pi
}
func main() {
// Example graph represented as an adjacency matrix
graph := [][]int{
{0, 2, 0, 6, 0},
{2, 0, 3, 8, 5},
{0, 3, 0, 0, 7},
{6, 8, 0, 0, 9},
{0, 5, 7, 9, 0},
}
// Run Dijkstra's algorithm with source s
d, pi := Dijkstra(graph, 0)
fmt.Println("From source s:")
fmt.Println("d:", d)
fmt.Println("pi:", pi)
// Run Dijkstra's algorithm with source z
d, pi = Dijkstra(graph, 4)
fmt.Println("From source z:")
fmt.Println("d:", d)
fmt.Println("pi:", pi)
}
在这个代码中,我们定义了一个优先队列来存储节点及其距离,并使用堆来维护队列的顺序。Dijkstra函数接受一个图的邻接矩阵和一个源节点,然后返回每个节点的最短距离数组d和前驱节点数组pi。
请注意,这个代码示例假设图是无向图,并且边权重是非负的。如果您的图是有向的或有负权边,您可能需要对代码进行相应的调整。
为了使用这个代码,您需要将您的图的邻接矩阵或邻接列表填充到graph变量中,并调用Dijkstra函数两次,一次使用s作为源节点,另一次使用z作为源节点。然后,您可以打印出每次while循环后的d值和pi值,以及集合S中的所有结点。
智谱清言:
由于我无法直接查看图 24-2,我将提供一个通用的Dijkstra算法的Go语言实现,并假设图24-2是一个加权有向图。我将按照您的要求,分别以结点
s
s
s和结点
z
z
z作为源点运行算法,并提供每次while循环后的
d
d
d值(从源点到每个顶点的最短路径长度)和
π
π
π值(最短路径树中的前驱节点),以及集合
S
S
S中的所有结点。
以下是Go语言的Dijkstra算法实现:
package main
import (
"container/heap"
"fmt"
)
type Edge struct {
to string
weight int
}
type Item struct {
vertex string
distance int
index int
}
type PriorityQueue []*Item
func (pq PriorityQueue) Len() int { return len(pq) }
func (pq PriorityQueue) Less(i, j int) bool {
return pq[i].distance < pq[j].distance
}
func (pq PriorityQueue) Swap(i, j int) {
pq[i], pq[j] = pq[j], pq[i]
pq[i].index = i
pq[j].index = j
}
func (pq *PriorityQueue) Push(x interface{}) {
n := len(*pq)
item := x.(*Item)
item.index = n
*pq = append(*pq, item)
}
func (pq *PriorityQueue) Pop() interface{} {
old := *pq
n := len(old)
item := old[n-1]
old[n-1] = nil
item.index = -1
*pq = old[0 : n-1]
return item
}
func (pq *PriorityQueue) update(item *Item, distance int) {
item.distance = distance
heap.Fix(pq, item.index)
}
type Graph map[string][]Edge
func Dijkstra(graph Graph, start string) (map[string]int, map[string]string, []string) {
dist := make(map[string]int)
prev := make(map[string]string)
pq := make(PriorityQueue, 1)
pq[0] = &Item{vertex: start, distance: 0}
heap.Init(&pq)
for pq.Len() > 0 {
item := heap.Pop(&pq).(*Item)
u := item.vertex
dist[u] = item.distance
for _, e := range graph[u] {
v := e.to
alt := dist[u] + e.weight
if _, exists := dist[v]; !exists || alt < dist[v] {
dist[v] = alt
prev[v] = u
heap.Push(&pq, &Item{vertex: v, distance: alt})
}
}
}
S := make([]string, 0, len(dist))
for vertex := range dist {
S = append(S, vertex)
}
return dist, prev, S
}
func main() {
graph := Graph{
"s": []Edge{{to: "t", weight: 10}, {to: "y", weight: 5}},
"t": []Edge{{to: "x", weight: 1}, {to: "y", weight: 2}},
"y": []Edge{{to: "t", weight: 3}, {to: "z", weight: 9}, {to: "x", weight: 2}},
"x": []Edge{{to: "z", weight: 4}},
"z": []Edge{},
}
distS, prevS, S := Dijkstra(graph, "s")
fmt.Println("Dijkstra from s:")
for _, vertex := range S {
fmt.Printf("Vertex: %s, Distance: %d, Predecessor: %s\n", vertex, distS[vertex], prevS[vertex])
}
distZ, prevZ, S := Dijkstra(graph, "z")
fmt.Println("\nDijkstra from z:")
for _, vertex := range S {
fmt.Printf("Vertex: %s, Distance: %d, Predecessor: %s\n", vertex, distZ[vertex], prevZ[vertex])
}
}
在这个代码中,我假设图24-2的结构与我提供的graph变量中的结构相似。您需要根据实际的图24-2来修改graph变量。
运行此代码将输出以
s
s
s和
z
z
z为源点时,每次while循环后的
d
d
d值和
π
π
π值,以及集合
S
S
S中的所有结点。由于Go语言的运行环境和图24-2的具体内容未知,我无法提供具体的输出结果。您需要在本地环境中运行此代码,并根据实际的图24-2来调整graph变量的内容。
天工:
要解决这个问题,我们首先需要理解Dijkstra算法的基本步骤,然后根据给定的图(虽然图没有实际展示,但我们可以假设一个图并进行解释)来运行算法。Dijkstra算法用于找到图中从一个源节点到所有其他节点的最短路径。以下是算法的步骤,以及如何用Go语言实现:
Dijkstra算法步骤
- 初始化所有节点的距离为无穷大,除了源节点的距离为0。
- 创建一个未处理节点的集合。
- 当未处理节点的集合不为空:
- 从集合中选择具有最小距离的节点,记为当前节点。
- 对于当前节点的所有邻居,计算从源节点到邻居的距离(通过当前节点)。
- 如果通过当前节点到邻居的距离更短,更新邻居的距离。
- 更新邻居的前驱节点。
- 将当前节点标记为已处理,从未处理节点集合中移除。
Go语言代码实现
package main
import (
"container/heap"
"fmt"
)
type Node struct {
index int
dist int
prev *Node
}
type MinHeap []*Node
func (h MinHeap) Len() int { return len(h) }
func (h MinHeap) Less(i, j int) bool { return h[i].dist < h[j].dist }
func (h MinHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] }
func (h *MinHeap) Push(x interface{}) {
*h = append(*h, x.(*Node))
}
func (h *MinHeap) Pop() interface{} {
old := *h
n := len(old)
x := old[n-1]
*h = old[0 : n-1]
return x
}
func dijkstra(graph [][]int, start int) {
n := len(graph)
dist := make([]int, n)
prev := make([]*Node, n)
visited := make([]bool, n)
for i := range dist {
dist[i] = 1<<31 - 1 // max int value as infinity
prev[i] = nil
}
dist[start] = 0
h := &MinHeap{}
heap.Init(h)
heap.Push(h, &Node{index: start, dist: 0})
for h.Len() > 0 {
cur := heap.Pop(h).(*Node)
if visited[cur.index] {
continue
}
visited[cur.index] = true
for i, weight := range graph[cur.index] {
if weight > 0 && (dist[cur.index]+weight < dist[i]) {
dist[i] = dist[cur.index] + weight
prev[i] = cur
heap.Push(h, &Node{index: i, dist: dist[i], prev: cur})
}
}
}
// Print results
for i, d := range dist {
fmt.Printf("Distance from %d to %d: %d, Path: ", start, i, d)
for p := prev[i]; p != nil; p = prev[p.index] {
fmt.Printf("%d -> ", p.index)
}
fmt.Println(i)
}
}
func main() {
// Example graph
graph := [][]int{
{0, 10, 3, 2, 0},
{10, 0, 1, 0, 5},
{3, 1, 0, 4, 0},
{2, 0, 4, 0, 2},
{0, 5, 0, 2, 0},
}
dijkstra(graph, 0) // Run Dijkstra from node 0
dijkstra(graph, 4) // Run Dijkstra from node 4
}
在上述代码中,我们定义了一个Node结构体,用于存储节点信息,包括节点的索引、距离和前驱节点。我们使用了container/heap包来管理最小堆,这有助于快速找到具有最小距离的节点。dijkstra函数实现了Dijkstra算法,从给定的源节点开始,计算到所有其他节点的最短距离和路径。
结果分析
由于没有具体的图24-2和图24-6,我们无法提供精确的d值和π值,以及集合S中的所有结点。但根据上述代码,你可以用任意图来运行Dijkstra算法,并得到类似图24-6风格的结果。每次while循环后,d表示从源节点到当前节点的最短距离,π表示前驱节点,集合S则包含了所有已处理(即已找到最短路径的)节点。
chatgpt:
在运行 Dijkstra 算法之前,首先让我们回顾一下它的基本步骤。Dijkstra 算法通过维护一个最优路径集合 $S$ 和对每个结点的最短路径估计(即距离)来寻找一张加权图中源结点到其他结点的最短路径。具体过程如下:
- 初始化:设置源结点的距离为0,其他结点的距离为无穷大。 集合 $S$ 开始是空的。
- 在未处理的结点中,选择当前距离最小的结点。
- 更新与当前结点相邻的未处理结点的距离。
- 将当前结点加入集合 $S$。
- 重复步骤2到4,直到所有结点都被处理。
输入示例
假设我们有一个图,以下是图的邻接矩阵作为输入的示例:
s, a, b, c, z
s 0, 1, 4, ∞, ∞
a ∞, 0, 2, 5, ∞
b ∞, ∞, 0, 1, 3
c ∞, ∞, ∞, 0, 2
z ∞, ∞, ∞, ∞, 0
Dijkstra 算法实现(Go语言)
以下是使用 Go 语言编写的 Dijkstra 算法的代码示例:
package main
import (
"fmt"
"math"
)
func dijkstra(graph [][]int, source int) (d []int, pi []int, S []int) {
n := len(graph)
d = make([]int, n)
pi = make([]int, n)
S = make([]int, 0)
// 初始化距离和前驱
for i := 0; i < n; i++ {
d[i] = math.MaxInt32
pi[i] = -1
}
d[source] = 0
// 主循环
for len(S) < n {
// 找到未处理结点中距离最小的结点
u := -1
for v := 0; v < n; v++ {
if !contains(S, v) && (u == -1 || d[v] < d[u]) {
u = v
}
}
if d[u] == math.MaxInt32 {
break
}
// 更新距离
S = append(S, u)
for v, weight := range graph[u] {
if weight != math.MaxInt32 && !contains(S, v) {
if d[u]+weight < d[v] {
d[v] = d[u] + weight
pi[v] = u
}
}
}
// 输出当前状态
fmt.Printf("S: %v, d: %v, π: %v\n", S, d, pi)
}
return
}
// 辅助函数,用于检查切片中是否包含某个元素
func contains(slice []int, item int) bool {
for _, a := range slice {
if a == item {
return true
}
}
return false
}
func main() {
// 定义图的邻接矩阵
graph := [][]int{
{0, 1, 4, math.MaxInt32, math.MaxInt32},
{math.MaxInt32, 0, 2, 5, math.MaxInt32},
{math.MaxInt32, math.MaxInt32, 0, 1, 3},
{math.MaxInt32, math.MaxInt32, math.MaxInt32, 0, 2},
{math.MaxInt32, math.MaxInt32, math.MaxInt32, math.MaxInt32, 0},
}
fmt.Println("从结点 s 开始:")
dijkstra(graph, 0) // s的索引为0
fmt.Println("\n从结点 z 开始:")
dijkstra(graph, 4) // z的索引为4
}
注意事项
- 请确保将图的邻接矩阵根据具体的情况进行修改。
math.MaxInt32用来表示无穷大,表示没有边相连的情况。
运行该程序将分别显示从结点 s 和结点 z 开始时每次迭代后集合 $S$、最短距离数组 $d$
kimi:
由于我没有图24-2的具体信息,我将提供一个通用的Dijkstra算法的Go语言实现,以及如何使用它来计算从源点到所有其他点的最短路径。你可以将图24-2的具体数据替换到代码中相应的部分。
Dijkstra算法是一种用于在加权图中找到单个源点到所有其他顶点的最短路径的算法。以下是Go语言实现的示例:
package main
import (
"fmt"
"math"
)
type Graph struct {
adjMatrix [][]int
}
type Node struct {
name string
distance float64
predicate *Node
}
func (g *Graph) Dijkstra(source string) map[string]Node {
nodes := make(map[string]Node)
for i, row := range g.adjMatrix {
for j, val := range row {
if val != 0 {
node := Node{
name: fmt.Sprintf("%d", i),
distance: math.MaxFloat64,
predicate: nil,
}
if i == j {
node.distance = 0
}
nodes[fmt.Sprintf("%d", j)] = node
}
}
}
var unvisited []string
for k := range nodes {
unvisited = append(unvisited, k)
}
var sourceNode *Node
for _, node := range nodes {
if node.name == source {
sourceNode = &node
break
}
}
for len(unvisited) > 0 {
var closest *Node
for _, node := range nodes {
if contains(unvisited, node.name) && (closest == nil || node.distance < closest.distance) {
closest = &node
}
}
unvisited = remove(unvisited, closest.name)
for _, neighbor := range nodes {
if contains(unvisited, neighbor.name) {
alt := closest.distance + g.adjMatrix[closest.nameToInt()][neighbor.nameToInt()]
if alt < neighbor.distance {
neighbor.distance = alt
neighbor.predicate = closest
}
}
}
}
return nodes
}
func (g *Graph) nameToInt() map[string]int {
nameToInt := make(map[string]int)
for i, row := range g.adjMatrix {
for j, val := range row {
if val != 0 {
nameToInt[fmt.Sprintf("%d", i)] = i
nameToInt[fmt.Sprintf("%d", j)] = j
}
}
}
return nameToInt
}
func contains(slice []string, val string) bool {
for _, item := range slice {
if item == val {
return true
}
}
return false
}
func remove(slice []string, val string) []string {
for i, item := range slice {
if item == val {
return append(slice[:i], slice[i+1:]...)
}
}
return slice
}
func main() {
adjMatrix := [][]int{
{0, 3, 0, 0, 0, 0, 0, 0},
{0, 0, 4, 0, 0, 0, 0, 0},
{0, 0, 0, 7, 1, 0, 0, 0},
{8, 0, 0, 0, 0, 2, 0, 0},
{0, 0, 0, 7, 0, 0, 1, 0},
{0, 0, 7, 4, 0, 0, 0, 2},
{0, 0, 0, 0, 7, 9, 0, 0},
{0, 0, 0, 0, 0, 0, 3, 0},
}
graph := Graph{adjMatrix: adjMatrix}
nodes := graph.Dijkstra("0")
for name, node := range nodes {
fmt.Printf("Node: %s, Distance: %.2f, Predecessor: %s\n", name, node.distance, node.name)
}
}
在这个代码中,Graph结构体表示图,Dijkstra方法实现了Dijkstra算法。你需要将图24-2的邻接矩阵替换到adjMatrix中,并根据需要调整源点。
每次while循环后的d值和π值以及集合S中的所有结点,你可以通过打印nodes映射的内容来获取。在实际的图24-2中,你需要根据图的结构来调整代码中的adjMatrix和源点。
请提供图24-2的具体信息,我可以帮你更精确地实现算法。
混元:
由于我无法直接查看图24-2和图24-6,我将提供一个通用的Dijkstra算法的Go语言实现,并解释如何在每次迭代后输出 d d d值、 π π π值和集合 S S S中的所有结点。
package main
import (
"container/heap"
"fmt"
)
type Edge struct {
to, cost int
}
type PriorityQueue []*Item
type Item struct {
value int
priority int
index int
}
func (pq PriorityQueue) Len() int { return len(pq) }
func (pq PriorityQueue) Less(i, j int) bool {
return pq[i].priority < pq[j].priority
}
func (pq PriorityQueue) Swap(i, j int) {
pq[i], pq[j] = pq[j], pq[i]
pq[i].index = i
pq[j].index = j
}
func (pq *PriorityQueue) Push(x interface{}) {
n := len(*pq)
item := x.(*Item)
item.index = n
*pq = append(*pq, item)
}
func (pq *PriorityQueue) Pop() interface{} {
old := *pq
n := len(old)
item := old[n-1]
old[n-1] = nil
item.index = -1
*pq = old[0 : n-1]
return item
}
func dijkstra(graph [][]Edge, start int) ([]int, []int) {
n := len(graph)
dist := make([]int, n)
prev := make([]int, n)
for i := range dist {
dist[i] = 1e9
prev[i] = -1
}
dist[start] = 0
pq := make(PriorityQueue, 0)
heap.Push(&pq, &Item{value: start, priority: 0})
S := make(map[int]bool)
for pq.Len() > 0 {
item := heap.Pop(&pq).(*Item)
u := item.value
if S[u] {
continue
}
S[u] = true
fmt.Printf("d values: %v\n", dist)
fmt.Printf("π values: %v\n", prev)
fmt.Printf("Set S: %v\n", S)
for _, edge := range graph[u] {
v := edge.to
if dist[u]+edge.cost < dist[v] {
dist[v] = dist[u] + edge.cost
prev[v] = u
heap.Push(&pq, &Item{value: v, priority: dist[v]})
}
}
}
return dist, prev
}
func main() {
graph := [][]Edge{
{{1, 4}, {2, 1}},
{{3, 1}},
{{1, 2}, {3, 5}},
{},
}
start := 0
dist, prev := dijkstra(graph, start)
fmt.Println("Final distances:", dist)
fmt.Println("Previous nodes:", prev)
start = 3
dist, prev = dijkstra(graph, start)
fmt.Println("Final distances:", dist)
fmt.Println("Previous nodes:", prev)
}
在这个实现中,dijkstra函数接受一个邻接表表示的图和一个起始节点。它返回两个数组:dist表示从源节点到每个节点的最短距离,prev表示在最短路径树中每个节点的前驱节点。
在每次迭代后,我们打印出当前的d值、π值和集合
S
S
S中的所有结点。请注意,这个实现假设图中没有负权边。
要运行此代码,请将其复制到一个名为main.go的文件中,并使用以下命令运行:
go run main.go
这将输出每次迭代后的d值、π值和集合
S
S
S中的所有结点。
